Battery electrode production method

ABSTRACT

According to the present invention, provided is a method for producing a battery electrode employing a configuration in which a compound material layer containing an active material  22  and a binder  54  is retained on a current collector  10 . The formation of the compound material layer is carried out by a method including: a step of forming a binder solution layer  56  by applying a binder solution  50  containing the first binder  54  to the current collector  10 ; a step of depositing the binder solution layer  56  and a compound material paste layer  46  on the current collector  10  by applying the compound material paste  40  over the binder solution layer  56 ; and a step of obtaining an electrode in which the compound material layer is formed on the current collector  10  by drying both the binder solution layer  56  and the compound material paste  40.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a national phase application of International Application No. PCT/JP2010/056534, filed Apr. 12, 2010, and claims the priority of Japanese Application No. 2009-179433, filed Jul. 31, 2009, the contents of both of which are incorporated herein by reference.

TECHNICAL FIELD

The present invention relates to a method for producing a battery electrode, and more particularly, to a method for producing a battery electrode having a configuration in which an electrode compound material layer containing an electrode active material is retained on a current collector.

BACKGROUND ART

Lithium ion batteries, nickel hydrogen batteries and other secondary batteries have recently become increasing important for use as vehicle-mounted power supplies or power supplies of personal computers and portable terminals. In particular, lithium secondary batteries, which are lightweight and provide high energy density, are expected to be preferably used as vehicle-mounted, high-output power supplies. In a typical configuration of this type of secondary battery, an electrode is provided that employs a configuration in which a material capable of reversibly occluding and releasing lithium ions (electrode active material) is retained on an electrically conductive member (electrode current collector). Typical examples of electrode active materials used in negative electrodes (negative electrode active materials) include carbon-based materials such as graphite carbon or amorphous carbon. In addition, typical examples of electrode current collectors used in negative electrodes (negative electrode current collectors) include sheet-like and foil-like members consisting mainly of copper or copper alloy.

In the production of a negative electrode having such a configuration, a typical example of a method for retaining the negative electrode active material on the negative electrode current collector consists of coating a compound material paste, in which a negative electrode active material powder and a binder are dispersed in a suitable medium, onto the negative electrode current collector (such as copper foil) followed by drying by passing through a hot air dryer and the like to form a layer containing the negative electrode active material (negative electrode compound material layer). In this case, the binder in the negative electrode compound material layer fulfills the role of binding the negative electrode active materials as well as binding between the negative electrode compound material layer and the negative electrode current collector. In addition, the binder in the negative electrode compound material layer also fulfills the role of binding the negative electrode compound material layer to the negative electrode current collector. Patent Documents 1 to 3 disclose examples of technical documents relating to this type of electrode production method.

-   Patent Document 1: Japanese Patent Application Laid-open No.     H11-283615 -   Patent Document 2: Japanese Patent Application Laid-open No.     2003-157847 -   Patent Document 3: Japanese Patent No. 3553244

DISCLOSURE OF THE INVENTION

However, in the production of a negative electrode as described above, when a compound material paste containing a negative electrode active material powder and a binder is coated onto a negative electrode current collector and dried, convection occurs during drying, and since binder in the vicinity of the current collector gathers (rises up) in the surface layer portion of the object coated with paste (opposite side of the current collector), the amount of the binder in the vicinity of the current collector decreases, thereby resulting in the problem of a decrease in adhesive strength (adhesion) between the negative electrode current collector and the negative electrode compound material layer. If the adhesive strength between the negative electrode current collector and the negative electrode compound material layer decreases, since the negative electrode compound material layer lifts off or peels from the negative electrode current collector in subsequent production steps (such as a step of winding a negative electrode sheet and positive electrode sheet in the form of a spiral) or during use of the battery, this can cause a decrease in battery performance. With the foregoing in view, the primary object of the present invention is to provide a battery electrode production method that is able to enhance adhesive strength (adhesion) between a current collector and a compound material layer.

According to the present invention, a method for producing a battery electrode employing a configuration in which a compound material layer containing an active material and a binder is retained on a current collector. The compound material layer is formed by applying a compound material paste containing the active material to the current collector followed by drying.

Here, formation of the compound material layer includes forming a binder solution layer by applying a binder solution containing a first binder to the current collector. In addition, it also includes depositing the binder solution layer and a compound material paste layer on the current collector by applying the compound material paste over the binder solution layer. Moreover, it also includes obtaining an electrode in which the compound material layer is formed on the current collector by drying both the deposited binder solution layer and compound material paste layer.

According to the method of the present invention, since the compound material paste layer is dried in a state in which the binder solution layer is formed between the current collector and the compound material paste layer, a large amount of binder in the binder solution layer is arranged at the interface between the compound material layer and current collector obtained after drying. As a result, adhesive strength between the compound material layer and the current collector can be enhanced.

Namely, although it is necessary to bind the compound material layer and the current collector relying only on the binder contained in the compound material paste layer in a conventional aspect in which the above-mentioned binder solution layer is not formed, in this conventional aspect, since the binder rises up in the surface portion of the compound material paste layer (opposite side of the current collector) if convection occurs during drying of the compound material paste layer, the amount of the binder in the vicinity of the current collector becomes inadequate, thereby resulting in problems such as a decrease in adhesive strength (adhesion) between the current collector and the compound material layer. In the method of the present invention, since binder in the binder solution layer, which has undergone phase separation from the compound material paste layer, is confined to the vicinity of the current collector even if convection has occurred during drying, an adequate amount of binder is ensured in the vicinity of the current collector. As a result, decreases in adhesive strength between the compound material layer and the current collector caused by segregation (migration) of binder attributable to convection during drying can be avoided, thereby making it possible to produce an electrode provided with a compound material layer that demonstrates favorable adhesion to the current collector.

In a preferable aspect disclosed herein, the binder solution is composed so as to be able to maintain a state of being separated from the compound material paste at least over a fixed period of time. As a result thereof, since mixing of the binder solution layer and the compound material paste layer is inhibited at least over a fixed period of time (and preferably the time from application of the compound material paste onto the binder solution to the drying thereof), a first binder 54 can be suitably retained in the vicinity of a current collector 10.

In a preferable aspect disclosed herein, a viscosity of at least one of the binder solution and the compound material paste is adjusted to a high viscosity of 1000 mPa·s or more. As a result, mixing between the binder solution layer and the compound material paste layer is suitably inhibited and a compound material layer demonstrating favorable adhesion is obtained. In general, the high viscosity as described above is suitably 1000 mPa·s or more, preferably 2000 mPa·s or more, and more preferably, for example, 3000 mPa·s or more (such as about 3000 to 20000 mPa·s). In addition, the viscosity (high viscosity) of one of the binder solution and the compound material paste is preferably adjusted to 2000 mPa·s or more (and preferably 3000 mPa·s or more), while the viscosity of the other one of the binder solution and the compound material past (low viscosity) is preferably adjusted to 1000 mPa·s or less (and preferably 500 mPa·s or less (for example, about 80 to 500 mPa·s or, for example, about 300 to 500 mPa·s)). As a result of imparting this difference in viscosities, the previously described mixing can be inhibited more effectively. In a preferable aspect disclosed herein, the compound material paste has the high viscosity, while the binder solution has the low viscosity. Furthermore, viscosity as referred to in the present invention is the viscosity obtained when measuring viscosity by rotating the rotor at 20 rpm after adjusting the temperature to 20° C. using a B type viscometer.

In a preferable aspect disclosed herein, a difference in solubility parameter (SP) values between the binder solution and the compound material paste is adjusted to 2.0 or more. As a result of imparting this difference in SP values, the previously described mixing can be suitably inhibited. In general, this difference in SP values is suitably made to be 2 or more, is normally preferably made to be 2 to 25, and is more preferably made to be, for example, 5 to 20. This difference in SP values can be realized by, for example, suitably selecting the solvent of the compound material paste and the solvent of the binder solution. For example, in the case a solvent of the compound material paste is water (SP value: 23.4) or N-methylpyrrolidone (SP value: 11.3), then carbon tetrachloride (SP value: 8.6) or a fluorine-based solution can be preferably used for the solvent of the binder solution.

In a preferable aspect disclosed herein, a specific gravity of the binder solution is adjusted so as to be higher than a specific gravity of the compound material paste. As a result of imparting this difference in specific gravity, the previously described mixing can be suitably inhibited. Means for inhibiting mixing as described above can be respectively used alone or used in combination.

In a preferable aspect disclosed herein, the compound material paste contains a second binder. In this case, active materials in the compound material layer can be more strongly bonded together by the second binder contained in the compound material paste layer.

In a preferable aspect disclosed herein, a content of the first binder per unit surface area of the binder solution layer is 60% by weight or more (and preferably within the range of 80 to 98% by weight) based on a total combined weight of a content of the first binder per unit surface area of the binder solution layer and a content of the second binder per unit surface area of the compound material paste layer. By dividing the contents of the first binder and the second binder in this manner, the distribution of binder in the compound material layer can be suitably controlled and problems attributable to segregation (migration) of binder can be resolved.

In a preferable aspect disclosed herein, the compound material paste layer can be dried rapidly since segregation of binder caused by migration is not required to be taken into consideration when setting the drying rate of the compound material paste layer. For example, a solvent present in the compound material paste layer can be volatilized at a rate of 0.2 mg/s or more (namely, 0.2 mg/s·cm² or more), and preferably 0.42 mg/s, per 1 cm² of liquid surface area. Consequently, electrode productivity is drastically improved.

In an aspect disclosed herein, the solvent of the compound material paste may contain water. In this case, carbon tetrachloride (CCl₄) or a fluorine-based liquid is preferably used for the solvent of the binder solution. Since carbon tetrachloride and fluorine-based liquids easily separate into two phases with water and have a large difference in specific gravity with water, they are preferably used as a binder solution suitable for the object of the present invention. In addition, in a preferable aspect disclosed herein, the solvent of the compound material paste contains N-methylpyrrolidone (NMP). In this case, carbon tetrachloride (CCl₄) or a fluorine-based liquid is preferably used for the solvent of the binder solution. Since carbon tetrachloride and fluorine-based liquids easily separate into two phases with N-methylpyrrolidone and have a large difference in specific gravity therewith, they are preferably used as a binder solvent suitable for the object of the present invention.

In an aspect disclosed herein, the binder solution layer is formed by spraying the binder solution. Although interface resistance between the current collector and compound material layer may increase and battery performance may decrease if the amount of the binder on the surface of the current collector is excessively large, since use of this method enables an atomized (granular) binder solution layer to be formed on the surface of the current collector, interface resistance between the compound material layer and the current collector can be reduced in comparison with the case of forming the binder solution layer over the entire surface of the current collector.

According to the present invention, a battery (for example, a lithium secondary battery) is also provided by using an electrode obtained according to any of the methods disclosed herein. In a preferable aspect disclosed herein, the electrode has a configuration in which a compound material layer containing an active material is retained on a current collector. When the compound material layer is divided into two equal parts at a central portion thereof in a direction of thickness, an amount of the binder contained in a divided portion arranged on a current collector side of the compound material layer is larger than an amount of the binder contained in a divided portion arranged on an opposite side from the current collector. Since this battery is composed by using the above-mentioned electrode for at least one of the electrodes, it demonstrates superior battery performance. For example, as a result of constructing a battery using the above-mentioned electrode, a battery can be provided that satisfies at least one (and preferably both) of high cycle durability and favorable productivity.

This type of battery is preferable for use as a battery installed in a vehicle such as an automobile. Thus, according to the present invention, a vehicle is provided that is equipped with any of the batteries disclosed herein (which may be in the form of a battery assembly in which a plurality of batteries are interconnected). In particular, the battery is preferably a lithium secondary battery (and typically, a lithium ion battery) since it is lightweight and allows the obtaining of a high output, and the vehicle (and typically, an automobile) is preferably provided with the lithium secondary battery as a motive power supply (and typically, a motive power supply of a hybrid vehicle or electric vehicle).

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional view schematically showing a negative electrode relating to an embodiment of the present invention;

FIG. 2 is a schematic drawing for explaining the relationship between specific gravities of a compound material paste and a binder solution and the separation into two phases by both;

FIG. 3 is a cross-sectional view schematically showing the production process of a negative electrode relating to an embodiment of the present invention;

FIG. 4 is a cross-sectional view schematically showing the production process of a negative electrode relating to an embodiment of the present invention;

FIG. 5 is a cross-sectional view schematically showing the production process of a negative electrode relating to an embodiment of the present invention;

FIG. 6 is a cross-sectional view schematically showing the production process of a negative electrode relating to an embodiment of the present invention;

FIG. 7 is a cross-sectional view schematically showing a production apparatus of a negative electrode relating to an embodiment of the present invention;

FIG. 8 is drawing schematically showing a battery relating to an embodiment of the present invention;

FIG. 9 is a side view of a vehicle installed with a battery relating to an embodiment of the present invention:

FIG. 10 is a graph indicating the relationship between binder division rate and peel strength relating to a test example of the present invention; and,

FIG. 11 is a drawing schematically showing a laminated cell relating to a test example of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION

The following provides an explanation of embodiments according to the present invention while referring to the drawings. In the following drawings, those members and sites demonstrating the same actions are explained using the same reference symbols. Furthermore, the dimensional relationships in each drawing (such as length, width and thickness) do not reflect actual dimensional relationships. In addition, matters other than those specifically mentioned in the present description that are required for carrying out the present invention (such as the configuration and production method of an electrode body provided with a positive electrode and negative electrode, the configuration and production method of a separator and electrolyte, batteries, or other general technical matters relating to battery construction) can be understood to be design matters for a person with ordinary skill in the art based on the prior art in the relevant field.

As shown in FIG. 1, the electrode production method disclosed herein is a production method of an electrode 30 having a configuration in which a compound material layer 20, containing an active material 22 and a first binder 54, is retained on a current collector 10. This compound material layer 20 is formed by applying a compound material paste 40 containing the active material 22 to the current collector 10 followed by drying (see FIG. 4).

In the electrode production method of the present embodiment, as shown in FIG. 3, a binder solution layer 56 is first formed by applying a binder solution 50 containing the first binder 54 to the current collector 10. Next, as shown in FIG. 4, the binder solution layer 56 and a compound material paste layer 46 are deposited on the current collector 10 by applying the compound material paste 40 over the binder solution layer 56. As shown in FIG. 5, the electrode 30 is obtained in which the compound material layer 20 is formed on the current collector 10 by drying both the deposited binder solution layer 56 and the compound material paste layer 46.

According to the production method relating to the present embodiment, since the compound material paste layer 46 is dried in a state in which the binder solution layer 56 is formed between the current collector 10 and the compound material paste layer 46, a large amount of the first binder 54 present in the binder solution 56 is arranged at the interface between the compound material layer 20 and the current collector 10 obtained after drying. As a result, adhesion (bonding strength) between the compound material layer 20 and the current collector 10 can be enhanced.

In providing a further explanation, in a conventional aspect in which the binder solution layer is not formed, although it is necessary to bond the compound material layer 20 and the current collector 10 by relying only on a binder (second binder) 44 contained in the compound material paste layer 46, in such an aspect, if convection occurs during drying of the compound material paste layer 46, the second binder 44 rises up in the surface portion of the compound material paste layer 46 (opposite side of the current collector 10), thereby causing the amount of the binder in the vicinity of the current collector 10 to be inadequate, which may cause adhesion (bonding strength) between the current collector 10 and the compound material layer 20 to decrease.

In contrast, in the method of the present embodiment, since the first binder 54 present in the compound material paste 46 and phase-separated binder solution layer 56 is confined to the vicinity of the surface of the current collector 10, an adequate amount of binder is secured in the vicinity of the current collector 10. As a result, decreases in bonding strength between the compound material layer 20 and the current collector 10 caused by segregation (migration) of binder due to convection during drying are avoided, and the electrode 30 can be produced that is provided with the compound material layer 20 that demonstrates favorable adhesion with the current collector 10.

In a preferable technology disclosed herein, the binder solution 50 is composed such that it is able to maintain a state in which it is separated from the compound material paste 40 over at least a fixed period of time. More specifically, as shown in FIG. 4, a state (liquid phase bilayer state) in which a liquid phase in the form of two layers consisting of the binder solution layer 56 and the compound material paste layer 46 is deposited can be formed at least from the time the compound material paste 40 is applied to the binder solution layer 56 until the time it is dried (for roughly 0.1 seconds or more, and for example, 1 to about 90 seconds or more, and normally for about 2 to 10 seconds or more). The configuration of the drying oven, drying conditions (temperature, time, air flow rate and the like), electrode body transport speed and the like are adjusted so that the compound material paste layer 46 becomes at least generally dry (for example, to an extent to which 50% by volume of the solvent has been volatilized and removed) during the time during which this separation is possible, namely during the time the two phases of the binder solution layer 56 and the compound material paste layer 46 are in a separated state (and typically, separated into two layers).

As a result, since mixing of the binder solution layer 56 and the compound material paste layer 46 is inhibited at least during the time from application of the compound material paste 40 to the binder solution layer 56 to the time it is dried, the first binder 54 can be suitably confined to the vicinity of the current collector 10.

Formation of the above-mentioned liquid phase bilayer state (inhibition of mixing) can be realized by, for example, making at least one of the binder solution and the compound material paste to have a high viscosity. For example, the viscosity of at least one of the binder solution and the compound material paste is adjusted to 1000 mPa·s or more (B type viscometer rotor, 20 rpm, 20° C.). As a result, mixing of the binder solution layer and compound material paste layer can be suitably inhibited. The higher viscosity as described above is suitably about 1000 mPa·s or more, is normally preferably 2000 mPa·s or more, and for example, is more preferably 3000 mPa·s or more. Although there are no particular limitations on the upper limit of the higher viscosity, it is generally about 20000 mPa·s, and normally preferably 10000 mPa·s or less (for example, 8000 mPa·s or less).

In addition, the viscosity (higher viscosity) of one of the binder solution and compound material paste is adjusted to 2000 mPa·s or more (and preferably 3000 mPa·s or more), while the viscosity of the other (lower viscosity) is adjusted to 1000 mPa·s or less (and preferably 500 mPa·s or less (for example about 80 to 500 mPa·s, or for example, about 300 to 500 mPa·s). As a result of providing such a difference in viscosity, the above-mentioned mixing can be more suitably inhibited. From the viewpoint of inhibiting mixing, the difference in viscosity between the binder solution and the compound material paste is suitably about 1000 mPa·s or more, normally preferably 2000 mPa·s or more, and for example, more preferably 2500 mPa·s or more (for example, within the range of 2500 to 8000 mPa·s). In a preferable aspect disclosed herein, the compound material paste has the higher viscosity while the binder solution has the lower viscosity.

The viscosities of the binder solution and the compound material paste can be adjusted by, for example, suitably adjusting the solid content in the liquid. For example, the viscosity of the compound material paste can be adjusted by suitably adjusting the solid concentrations of active material, binder and other components forming the compound material layer (such as electrically conductive materials) in the compound material paste. In addition, the viscosity of the binder solution can be adjusted by suitably adjusting the binder concentration in the binder solution. Alternatively, the above viscosities may also be adjusted to be within the preferable ranges by adding a thickener (and typically, a polymer material). In the case of inhibiting mixing by utilizing viscosity in the manner described above, the same solvent (such as water) can be used for the compound material paste and the binder solution.

An example of another method for realizing the above-mentioned liquid phase bilayer state (inhibition of mixing) is a method that imparts a difference in SP values. Preferably, the difference in SP values between the binder solution and the compound material paste is adjusted to be 2.0 or more. The above-mentioned mixing can be suitably inhibited by imparting a difference in SP values in this manner. Generally, the difference in SP values is suitably 2 or more, normally preferably 2 to 25, and more preferably, for example, 5 to 20.

A difference in SP values within the above-mentioned ranges can be realized by suitably selecting the solvent of the compound material paste and the solvent of the binder solution. For example, in the case the solvent of the compound material paste is water (SP value: 23.4) or N-methylpyrrolidone (SP value: 11.3), then carbon tetrachloride (SP value: 8.6) or a fluorine-based liquid can be preferably used for the solvent of the binder solution. Alternatively, even in the case of using the same solvent for the solvent of the compound material paste and the solvent of the binder solution, a difference in SP values that is within the above-mentioned ranges can be realized by suitably selecting other material components that compose the compound paste and the binder solution (active material, binder and other components that form the compound material layer).

An example of another method for realizing the above-mentioned liquid phase bilayer state (inhibition of mixing) is a method that imparts a difference in specific gravity. Preferably, the specific gravities are adjusted such that the specific gravity of the binder solution is higher than the specific gravity of the compound material paste. As a result of imparting a difference in specific gravities in this manner, the above-mentioned mixing can be suitably inhibited. Methods for realizing the liquid phase bilayer state as described above can each be used alone or can be used in combination.

Furthermore, as shown in FIG. 4, when forming the liquid phase bilayer state as previously described, a portion 54 a of the first binder in the binder solution layer 56 is diffused in the compound material paste 46. As a result of diffusing the portion 54 a of the first binder in the compound material paste layer 46 in this manner, the amount of the binder in the vicinity of the current collector is adjusted to a suitable amount, and an electrically conductive path is secured between the current collector 10 and the compound material layer 20. In addition, active material 22 present in the compound material layer can be adhered together by the first binder 54 a diffused into the compound material paste layer 46.

In addition, in the technology disclosed herein, the compound material paste 40 (compound material paste layer 46) contains the second binder 44. This second binder 44 may be of the same material (and typically, a polymer material) or a different material from the first binder 54. In this case, active material present in the compound material layer is more strongly bound together by the second binder contained in the compound material paste layer.

In a preferable aspect disclosed herein, the content of the first binder per unit surface area of the binder solution layer is 60% by weight or more (for example, 70 to 99% by weight, and preferably 80 to 98% by weight (for example, about 95% by weight)) based on the combined total of the content of the first binder per unit surface area of the binder solution layer and the content of the second binder per unit surface area of the compound material paste layer. By dividing the contents of the first binder and the second binder in this manner, the distribution of binder in the compound material layer obtained after drying can be suitably controlled, and problems attributable to segregation of binder can be resolved.

As shown in FIG. 5, although there are no particular limitations thereon, the degree of uneven distribution of binder when the compound material layer 20 is divided into two parts in the center in the vertical direction (direction of thickness) (amount of bonder in an upper layer side 20B/amount of binder in a lower layer side 20A) is generally within the range of 0.15 to 1.0, and for example, about 0.3 to 1.0. If the degree of uneven distribution of binder exceeds 1.0 (namely, a state in which the amount of the binder of the upper layer side 20B is greater than the amount of the binder of the lower layer side 20A), adhesion between the compound material layer 20 and the current collector 10 may decrease due to a shortage of binder of the compound material layer 20 in the vicinity of the current collector 10. On the other hand, if the degree of uneven distribution of binder is less than 0.15 (namely, a state in which the amount of the binder of the lower layer side 20A is far greater than the amount of the binder of the upper layer side 20B), there is increased susceptibility to the occurrence of slippage and the like of the active material 22 in the surface portion of the compound material layer due to a shortage of binder in the vicinity of the surface portion of the compound material layer 20. Thus, generally the degree of uneven distribution of binder is suitably 0.15 to 1.0, preferably, for example, 0.3 to 1.0, and normally more preferably 0.6 to 1.0.

The following provides a more detailed explanation of an embodiment of the present invention. In the present embodiment, a liquid phase bilayer state composed of a binder solution layer and a compound material paste layer is formed by imparting a difference in SP values and a difference in specific gravity. In this electrode production method, the binder solution layer 50 is prepared in which the binder 54 is dispersed in a solvent 52 capable of separating into two phases with a solvent 42 of the compound material paste 40, and the specific gravity of the binder solution 50 is higher than that of the compound material paste 40. The relationship between the binder solution 50 and the compound material paste 40 is schematically shown in FIG. 2. The binder solution 50 is composed of a solvent (such as CCl₄) 52 capable of separating into two phases with a solvent (such as water) 42 of the compound material paste. For example, a solvent that spontaneously separates into two phases (namely, a phase-separable solvent) when allowed to stand undisturbed after stirring and mixing both solvents can be used preferably. In addition, the specific gravity of the binder solution 50 is higher than that of the compound material paste 40. Consequently, when both are mixed and allowed to stand undisturbed, the solvents separate into two phases such that the binder solution 50 becomes the lower layer.

Next, as shown in FIG. 3, the binder solution layer (binder layer) 56 is formed by applying the binder solution 50 to the surface of the current collector 10. This binder solution layer (binder layer) 56 is typically a liquid layer composed of the binder solution 50.

Next, as shown in FIG. 4, the compound material paste 40 is applied to the current collector 10 over the binder solution layer 56. At that time, since the binder solution layer 56 is composed of the solvent 52 capable of separating into two phases with the solvent 42 of the compound material layer, it does not readily mix with the compound material paste 40 (and preferably, the binder solution layer 56 and the compound material paste layer 46 (compound material paste 40) are separated into two phases). In addition, since the binder solution layer 56 has a higher specific gravity than the compound material paste layer 46 (compound material paste 40), when the compound material paste 40 is applied over the binder solution layer 56, the binder solution layer 56 and the compound material paste layer 46 (compound material paste 40) do not readily mix, and the binder solution layer 56 is easily confined to the vicinity of the surface of the current collector 10 (lower layer).

Subsequently, by drying both the deposited binder solution layer 56 and the compound material paste layer 46, the electrode 30 is obtained in which the compound material layer 20 is formed on the current collector 10 as shown in FIG. 5.

According to this electrode production method, since the compound material paste layer 46 is dried in a state in which the binder solution layer 56 is formed between the current collector 10 and the compound material paste layer 46, the first binder 54 of the binder solution layer 56 is arranged at the interface of the compound material layer 20 and the current collector 10 obtained after drying. As a result, adhesive strength between the compound material layer 20 and the current collector 10 can be enhanced.

Although not intended to be particularly limiting, the following provides a more detailed explanation of the present embodiment with reference to FIGS. 2 to 5 by primarily using as an example the case of producing a negative electrode for a lithium secondary battery (and typically, a lithium ion battery).

Namely, in this embodiment, a binder solution 50 is prepared in which the first binder 54 is dispersed in the solvent (binder solvent) 52 capable of separating into two phases with the solvent (paste solvent) 42 of the compound material paste 40 as shown in FIG. 2.

There are no particular limitations on the binder (first binder 54) used for the binder solution, and it may be the same as that used in a typical negative electrode for a lithium secondary battery. A water-soluble or water-dispersible polymer can be used such as styrene butadiene rubber (SBR), carboxymethyl cellulose (CMC), polytetrafluoroethylene (PTFE), polyethylene (PE) or polyacrylic acid (PAA). Alternatively, an organic solvent-based polymer such as polyvinylidene fluoride (PVDF) or polyvinylidene fluoride-hexafluoropropylene (PVDF-HFP) copolymer can be used. In this embodiment, SBR is used for the binder.

The solvent (binder solvent) used for the binder solution 50 preferably has a specific gravity higher than the solvent of the compound material paste and is capable of separating into two phases with the solvent of the compound material paste. For example, a solvent having a difference in solubility parameter with the solvent of the compound material paste of 2 or more (such as that having a difference in solubility parameter of about 2 to 25) can be preferably used for the binder solvent 52. In addition, the binder solvent 52 is preferably a solvent that is able to uniformly disperse or dissolve the binder used. More specifically, examples of binder solvents that can be preferably used in the case the dispersion solvent of the compound material paste is water include carbon tetrachloride (CCl₄), chloroform (CHCl₃), trichloroethane (C₂H₃Cl₃) and trichloroethylene (C₂HCl₃). In addition, a fluorine-based liquid may also be used that has a difference in SP value with water of 2 or more and has a higher specific gravity than water. One type or two or more types thereof can be suitably selected and used. Furthermore, a fluorine-based liquid as referred to here indicates a solvent (and typically, an organic solvent) containing fluorine (F) as a constituent element thereof. An example of a commercially available product of a fluorine-based liquid able to be used preferably in the technology disclosed herein is a member of the “Fluorinate®” series manufactured by the 3M Corp. In addition, CCl₄ is an example of a binder solvent that can be preferably used in the case the paste solvent is N-methylpyrrolidone (NMP). In addition, a fluorine-based liquid may be used that has a difference in SP value of 2 or more with N-methylpyrrolidone and has a specific gravity higher than that of N-methylpyrrolidone. CCl₄ is used for the binder solvent in this embodiment.

The binder solution can be prepared by dispersing the binder 54 in the solvent 52. As a result, the binder solution 50 is obtained in which the binder 54 is dispersed in the solvent 52. Furthermore, although FIGS. 2 to 4 depict a state in which the binder 54 is dispersed in the solvent 52 while maintaining a granular form, the present invention is not limited thereto, but rather the binder 54 may also be dissolved in the binder 52 without maintaining a granular form.

Although there are no particular limitations on the concentration (solid concentration) of the binder in the binder solution, if the binder concentration is excessively high, solution coatability becomes poor, while if the binder concentration is excessively low, the drying rate becomes slow which may cause a decrease in productivity. Thus, the binder concentration (solid concentration) is preferably roughly 5 to 50% by weight, and more preferably roughly 15 to 25% by weight.

Once the binder solution has been prepared in this manner, the binder solution layer 56 is then formed by applying (and typically, coating) the binder solution 50 to the current collector 10 as shown in FIG. 3. A current collector composed of a metal having favorable electrical conductivity (for example, a metal such as aluminum, nickel, copper or stainless steel, or alloy having such a metal as the main component thereof) can be preferably used for the current collector 10. For example, in the case of producing a negative electrode for a lithium secondary battery, a current collector made of copper (referring to that composed of copper or alloy composed mainly of copper (copper alloy)) is used preferably.

Examples of procedures for applying (coating) the binder solution to the current collector that can be preferably employed include ordinary technologies for coating fluidic materials, such as a printing method (ink jet method, relief printing, gravure printing, screen printing and the like), fluid dispenser method, spray method or nanowire coating method. A method in which the binder solution is coated onto the surface of the current collector using a spray method can be preferably used for the method for coating the binder solution onto the surface of the current collector in the technology disclosed herein. Alternatively, another example is a method in which the binder solution is coated in the form of a layer onto the surface of the current collector using a dispenser. As a result, the binder solution layer 56 can be formed having a uniform thickness. Although there are no particular limitations on the thickness of the binder solution layer, it can normally be 1.5 to 6 μm and, for example, is suitably about 2 to 4 μm.

Although there are no particular limitations on the coated amount of the binder solution (coated amount per unit surface area of the current collector), if the coated amount of the binder solution is excessively low, the amount of the binder contained in the solution becomes excessively low, and this may prevent the effect of enhancing adhesive strength between the current collector 10 and the compound material layer 20 from being adequately obtained. On the other hand, if the coated amount of the binder solution is excessively high, the amount of the binder contained in the solution becomes excessively high, and this may cause a decrease in battery performance due to an increase in interface resistance between the current collector 10 and the compound material layer 20. Thus, the coated amount of the binder solution as the solid content (namely, as the weight of the binder after drying) is preferably adjusted so as to be roughly about 0.01 to 0.05 mg/cm² and normally 0.02 to 0.03 mg/cm². Furthermore, the compound material layer 20 may also be provided on both sides of the current collector 10 instead of on just one side of the current collector 10. In the case of providing the compound material layer 20 on both sides of the current collector 10, an aspect can be preferably employed in which the binder solution layer 56 is formed by coating the binder solution 50 onto both sides of the current collector 10.

Once the binder solution layer 56 has been formed in this manner, the binder solution layer 56 and the compound material paste layer 46 are then deposited on the current collector 10 by applying (and typically, coating) the compound material paste 40 over the binder solution layer 56 as shown in FIG. 4.

The compound material paste 40 can be prepared by mixing the negative electrode active material (and typically, a powdered form thereof) 22 with another negative electrode compound material layer forming component (such as the binder 44) used as necessary in a suitable solvent 42.

There are no particular limitations on the negative electrode active material (and typically, a powdered form thereof) 22, and it may be the same as that used in a typical lithium ion secondary battery. Typical examples of the negative electrode active material 22 used for the negative electrode include carbon-based materials such as graphite carbon or amorphous carbon, lithium transition metal composite oxides (such as lithium titanium composite oxides), and lithium transition metal composite nitrides.

Preferable examples of the solvent 42 used for the compound material paste 40 include water and mixed solvents composed mainly of water (aqueous solvents). One type or two or more types of organic solvents able to uniformly mix with water (such as lower alcohols or lower ketones) can be suitably selected and used for the solvent other than water that composes this mixed solvent. The solvent 42 is not limited to an aqueous solvent, but rather may also be a non-aqueous solvent. An example of a non-aqueous solvent that can be used is N-methylpyrrolidone (NMP).

In addition to the negative electrode active material 22, the compound material paste 40 can contain as necessary a material used in compound material pastes for forming a negative electrode compound material layer in the production of an ordinary negative electrode. Typical examples of such materials include electrical conductive materials and the binder (second binder) 44. Examples of electrically conductive materials that can be used include carbon powder such as carbon black (including acetylene black) and electrically conductive metal powders such as nickel powder. The second binder 44 fulfills the role of binding negative electrode active material particles together. This second binder 44 may be the same material as the first binder 54 contained in the binder solution layer 56 or a different material.

The technology disclosed herein can be preferably carried out in an aspect in which the same binder is used for the compound material paste layer 46 and the binder solution layer 56. In the case the compound material paste layer 46 contains a plurality of types of binders, at least one type thereof is preferably the same binder as that of the binder solution layer 56.

The technology disclosed herein can also be preferably carried out in an aspect in which different binders are used for the compound material paste layer 46 and the binder solution layer 56. In this case, there is the advantage of being able to easily analyze and confirm the binder component originating in the binder solution. In this case, a binder can be preferably selected for the first binder 54 contained in the binder solution layer that is readily soluble in the solvent 52 of the binder solution and poorly soluble in the solvent 42 of the compound material paste. As a result, diffusion of the first binder 54 in the compound material paste layer is suitably inhibited, and an amount of binder can be suitably secured in the vicinity of the current collector.

The procedure for applying (and typically, coating) the compound material paste 40 to the current collector 10 can be carried out in the same manner as production of a negative electrode for an ordinary lithium secondary battery of the prior art with the exception of using a current collector in which the binder solution layer 56 is formed on the surface thereof as previously described for the current collector. For example, the compound material paste layer 46 can be formed by coating a prescribed amount of the compound material paste 40 onto the current collector 10 over the binder solution layer 56 using a suitable coating apparatus (such as a die coater).

Here, the binder solution layer 56 is composed of the solvent 52 capable of separating into two phases with the solvent 42 of the compound material paste. Consequently, since the binder solution layer 56 and the compound material paste layer 46 do not readily mix (and preferably, the binder solution layer 56 and the compound material paste layer 46 are in a state in which they are separated into two phases) during the time from application of the compound material paste onto the binder solution layer to drying of the compound material paste layer, the binder is easily confined to the vicinity of the surface of the current collector. In addition, the specific gravity of the binder solution 50 is higher than that of the compound material paste 40. Consequently, the binder solution layer 56 is easily confined to the vicinity of the surface of the current collector 10 (lower layer) during the time from application of the compound material paste onto the binder solution layer to drying of the compound material paste layer. Thus, an amount of binder is easily secured in the vicinity of the current collector.

Once the binder solution layer 56 and the compound material paste layer 46 have been deposited on the current collector 10 in this manner, as shown in FIG. 5, the negative electrode 30, in which the negative electrode compound material layer 20 is formed on the current collector 10, is then obtained by drying both the deposited binder solution layer 56 and the compound material paste layer 46.

The temperature at which both the binder solution layer 56 and the compound material paste layer 40 are dried is within a temperature range at which both the solvent 52 of the binder solution layer and the solvent 42 of the compound material paste layer can be volatilized. For example, in the case the solvent of the binder solution layer is CCl₄ and the solvent of the compound material paste is water, then the drying temperature can be made to be roughly about 70 to 160° C., and normally preferably 80 to 120° C.

Although it is necessary to bind the compound material layer 20 and the current collector 10 relying only on the second binder 44 contained in the compound material paste layer 46 in a conventional aspect in which the binder solution layer 56 is not formed, in this conventional aspect, since the second binder 44 rises up in the surface portion of the compound material paste layer 46 (opposite side of the current collector 10) if convection occurs during drying of the compound material paste layer 46 when drying is carried out rapidly, the amount of the binder in the vicinity of the current collector 10 becomes inadequate, thereby resulting in problems such as a decrease in adhesive strength (adhesion) between the current collector 10 and the compound material layer 20.

In contrast, in the present embodiment, since the compound material paste layer 46 is dried in a state in which the binder solution layer 56 is formed between the negative electrode current collector 10 and the compound material paste 40, even if convection occurs during rapid drying of the compound material paste layer 46, since the binder (first binder) 54 in the binder solution layer 56 that has separated from the compound material paste 40 is confined to the vicinity of the surface of the current collector 10, an amount of binder is secured in the vicinity of the current collector 10. As a result, decreases in adhesive strength between the compound material layer and the current collector 10 attributable to segregation (migration) of binder caused by convection during drying can be avoided, and a high-performance electrode 30 can be produced that is provided with the compound material layer 20 that demonstrates favorable adhesion to the current collector 10. The use of this method enables the compound material paste layer 46 to be dried rapidly since it is not necessary to consider binder segregation (migration) caused by convection when setting the drying rate of the compound material paste layer 46. For example, the solvent of the compound material paste layer can be volatilized at a high rate of 0.2 mg/s·cm² or more, thereby improving productivity. Although there are no particular limitations on the upper limit of the drying rate, it is, for example, about 0.78 mg/s·cm².

Production of the negative electrode 30 relating to the present embodiment is completed in this manner. Furthermore, the thickness and density of the negative electrode compound material layer 20 can be adjusted by carrying out suitable press processing (such as roll press processing) as necessary after drying the compound material paste 40.

The cross-sectional structure of the negative electrode 30 for a lithium secondary battery preferably produced by applying the electrode production method disclosed herein is schematically shown in FIG. 5. The negative electrode 30 has a configuration in which the negative electrode compound material layer 20 containing the negative electrode active material 22 is retained on the current collector 10. As shown in FIG. 4, this negative electrode compound material layer 20 is formed by forming the binder solution layer 56 between the current collector 10 and the compound material paste layer 46 followed by drying both the binder solution layer 56 and the compound material paste 40. Consequently, when the resulting negative electrode compound material layer 20 is divided into two equal parts at the central portion thereof in the direction of thickness, the amount of the binder contained in the divided portion 20A arranged on the current collector 10 side of the compound material layer 20 is greater than the amount of the binder contained in the divided portion 20B arranged on the opposite side from the current collector 10. Namely, the degree of binder segregation when the compound material layer 20 is divided into two equal parts at the central portion thereof in the vertical direction (direction of thickness) (namely, the amount of the binder of the upper layer 20B/amount of the binder of the lower layer 20A) is less than 1.0 (namely, a state in which the amount of the binder of the upper layer 20B is greater than the amount of the binder of the lower layer 20A). As a result, a larger amount of binder is arranged on the surface of the current collector 10, and adhesive strength between the negative electrode compound material layer 20 and the current collector 10 can be enhanced. Furthermore, the distribution of binder in the compound material layer can be investigated in the case the binder is SBR, for example, by observing a distribution cross-section of the binder dyed with Br or Os (osmium) using an electron probe microanalyzer (EPMA).

Furthermore, although the binder solution layer 56 is formed continuously over the entire range (entire area) over which the compound material paste layer 46 is applied in the example described above as shown in FIG. 4, the present invention is not limited thereto. For example, as shown in FIG. 6, the binder solution layer 56 can also be formed sporadically in the form of dots over the range in which the compound material paste layer 46 is applied. In this case, formation of the binder solution layer 56 is carried out by, for example, spraying the binder solution 50 onto the surface of the current collector 10. The use of spraying enables the binder solution layer 56 to be formed in the form of dots on the surface of the current collector.

Since the contact surface area between the current collector 10 and the compound material layer 20 can be increased in the case of forming the binder solution layer 56 in the form of dots in this manner as compared with forming over the entire surface, interface resistance between the current collector 10 and the compound material layer 20 can be reduced. On the other hand, since the amount of the binder on the surface of the current collector 10 increases in the case of forming the binder solution layer 56 over the entire surface as compared with forming in the form of dots, the adhesion strength between the current collector 10 and the compound material layer 20 can be increased. In a preferable technology disclosed herein, roughly 60% or more (and preferably, about 60 to 80%) of the region (range) of the surface of the current collector 10 over which the compound material paste 40 is applied is preferably covered by the binder solution layer 56. As a result of covering this range, adhesive strength between the compound material layer and current collector is enhanced while inhibiting increases in interface resistance between the compound material layer and current collector, thereby making it possible to realize both interface resistance and adhesive strength at high levels.

Next, an explanation is provided of a production apparatus 90 for producing the negative electrode 30 while additionally referring to FIG. 7. This production apparatus 90 is provided with rollers 91 and 92, a spraying apparatus 94, a die coater 96 arranged downstream from the spray apparatus 94 in the direction of current collector transport, a drying oven 98 arranged downstream from the die coater 96 in the direction of current collector transport, and a take-up unit 99 that takes up the current collector 10 that has passed through the drying oven 98.

The long sheet-like current collector 10 is unwound from an unwinding unit not shown, and transported through the apparatus by rotation of the rollers 91 and 92. The binder solution 50 is housed in the spraying apparatus 94. By the spraying apparatus 94, the binder solution 50 is sprayed onto the surface of the current collector 10 during transport to form the binder solution layer. The current collector 10 on which the binder solution layer has been formed on the surface thereof is sent to the die coater 96 by the rollers 91 and 92. The compound material paste 40 is housed in the die coater 96. By the die coater 96, the compound material paste 40 is coated over the binder solution layer onto the surface of the current collector 10 during transport, and the binder solution layer and the compound material paste layer are deposited on the current collector 10. The current collector 10 on which has been deposited the binder solution layer and the compound material paste layer is then sent to the drying oven 98. The temperature in the drying oven 98 is set to, for example, about 80 to 150° C., and the transport speed of the current collector 10 is set to, for example, about 30 to 50 m/min. As a result of passing the current collector 10 through the drying oven 98 under these conditions, the binder solution layer and the compound material paste layer deposited on the current collector 10 are dried, and the negative electrode 30 is obtained in which the compound material layer 20 is formed on the current collector 10. The negative electrode 30 is then taken up by the take-up unit 99 and supplied to the next step.

Next, the following experiments were carried out as examples in order to confirm that the adhesive strength between the current collector and the compound material layer is enhanced by using the method of the present embodiment.

Test Example 1

In Sample 1, the negative electrode 30 was produced by preparing a binder solution and compound material paste having different SP values and specific gravities. More specifically, the binder solution 50 (solid concentration: 10%) was prepared by using styrene butadiene rubber (SBR) for the first binder 54 and dispersing this in a solvent composed of carbon tetrachloride (CCl₄, SP value: 8.6, specific gravity: 1.58). In addition, the compound material paste 40 was prepared by using carbon powder for the negative electrode active material 22, using carboxymethyl cellulose (CMC) as a thickener, and dispersing these in water (SP value: 23.4, specific gravity: 1.00) so that the weight ratio of these materials was 99:1.

Next, a copper foil 10 on which was provided the binder solution layer 56 in the form of dots was produced by coating the binder solution 50 onto a long sheet-like copper foil (current collector 10) by spraying. The coated amount of the binder solution 50 was adjusted to be roughly 0.025 mg/cm² (as solid content). The binder solution layer 56 and the compound material paste layer 46 were then deposited on the copper foil (current collector 10) by applying the compound material paste 40 over the binder solution layer 56, and the negative electrode 30, in which the negative electrode compound material layer 20 was provided on the surface of the current collector 10, was obtained by drying both at 80° C.

In addition, for the sake of comparison, a negative electrode sheet was produced without coating the binder solution 50 onto the current collector 10 in Sample 2. The compound material paste was prepared by using carbon powder for the negative electrode active material, using SBR for the binder, using CMC as a thickener, and dispersing these materials in water at a weight ratio of 99:1:1, and this was then coated onto the current collector (copper foil) and dried to obtain a negative electrode sheet in which the negative electrode compound material layer was provided on the surface of the current collector.

Adhesion between the current collector 10 and the negative electrode compound material layer 20 of the negative electrode sheets relating to Samples 1 and 2 obtained in this manner was evaluated with a 90° peel test using a tensile tester. The results are shown in Table 1. As shown in Table 1, in Sample 1 in which the binder solution was coated onto copper foil (current collector), peel strength improved considerably as compared with Sample 2 in which the binder solution was not coated onto copper foil (current collector). More specifically, the peel strength for Sample 1 was 2.8 N/m, while the peel strength for Sample 2 was 0.8 N/m. On the basis of these results, coating the binder solution onto the copper foil (current collector) was confirmed to considerably improve adhesive strength.

TABLE 1 Solvent of compound Solvent of binder Peel strength material paste solution (N/m) Sample 1 Water CCl₄ 2.8 Sample 2 Water None 0.8

Test Example 2

In Samples 3 to 6, the negative electrode 30 was produced by preparing binder solutions and compound material pastes having different viscosities. More specifically, binder solutions having viscosities of 80 mPa·s, 200 mPa·s, 300 mPa·s and 400 mPa·s, in order from Sample 3 to Sample 6, were prepared by dispersing SBR serving as the binder 54 in suitable amounts of water (see Table 2). In addition, carbon powder serving as the negative electrode active material 22 and carboxymethyl cellulose (CMC) serving as a thickener were dispersed in a suitable amount of water so that the weight ratio of these materials was 99:1 to prepare a compound material paste having a viscosity of 3000 mPa·s. Furthermore, the viscosities of the binder solutions and compound material pastes were measured using a B type viscometer by adjusting the temperature to 20° C. and rotating the rotor at 20 rpm.

TABLE 2 Compound material Binder solution Peel paste viscosity viscosity strength (mPa · s) (mPa · s) (N/m) Sample 3 3000 80 2.33 Sample 4 3000 200 2.21 Sample 5 3000 300 2.02 Sample 6 3000 400 1.80 Sample 7 — — 1.16 (ordinary electrode)

Next, the binder solution was coated onto a long sheet-like copper foil (current collector 10) into the form of a strip with a dispenser to produce the copper foil 10 in which the binder solution 56 was provided in the form of a strip. The coated amount of the binder solution 50 was adjusted to roughly 0.0245 mg/cm² (as solid content). The binder solution layer 56 and the compound material paste layer 46 were then deposited on the copper foil (current collector) 10 by applying the compound material paste 40 over the binder solution layer 56, and the negative electrode 30, in which the negative electrode compound material layer 20 was provided on the surface of the current collector 10, was obtained by drying both at 80° C.

In addition, for the sake of comparison, a negative electrode sheet was produced without coating the binder solution 50 onto the current collector 10 (to be referred to as an ordinary electrode) in Sample 7. More specifically, the compound material paste was prepared by dispersing carbon powder serving as the negative electrode active material, SBR serving as a binder, and CMC serving as a thickener in water so that the weight ratio of these materials was 98:1:1, followed by coating onto the current collector (copper foil) and drying to obtain the negative electrode sheet in which the negative electrode compound material layer is provided on the surface of the current collector.

Adhesion between the current collector 10 and the negative electrode compound material layer 20 of the negative electrode sheets relating to Samples 3 to 6 obtained in this manner was evaluated with a 90° peel test using a tensile tester. Those results are shown in Table 2.

As is clear from Table 2, in Sample 7 (ordinary electrode) in which the negative electrode sheet was produced without coating the binder solution layer onto the current collector, peel strength decreased due to insufficient binder in the vicinity of the current collector caused by segregation of the binder during drying. In contrast, in any of Samples 3 to 6 in which the negative electrode sheets were produced by coating the binder solution layer onto the current collector, peel strength was confirmed to increase considerably in comparison with Sample 7 (ordinary electrode). In the case of the prototype negative electrode sheets produced in this example, extremely high peel strength of 2.0 N/m or more (and typically, 2.02 to 2.33 N/cm) was obtained by adjusting the viscosity of the compound material paste to 300 mPa·s and the viscosity of the binder solution to 300 mPa·s or less. Moreover, based on a comparison of Samples 3 to 6, peel strength was confirmed to further increase as the difference in viscosity between the compound material paste and the binder solution become larger. In the case of the prototype negative electrode sheets produced in this example, the difference in viscosity between the binder solution and the compound material paste is 2000 mPa·s or more (Samples 3 to 6), preferably 2700 mPa·s or more (Samples 3 to 5), more preferably 2800 mPa·s or more (Samples 3 and 4) and optimally 2920 mPa·s or more (Sample 3).

Test Example 3

In Samples 8 to 14, the negative electrodes 30 were produced in the same manner as the above-mentioned Sample 3 with the exception of allocating a portion of the binder contained in the binder solution to the compound material paste as well. More specifically, the negative electrodes were produced by dividing the destinations of the binder between the binder solution layer and the compound material paste layer while maintaining a total coated amount of binder throughout of 0.0245 mg/cm² (as solid content). In Samples 8 to 14, the division rates at which the binder was allocated to the binder solution layer were adjusted to be as shown in Table 3. Here, the binder division rate (%) is expressed as [binder coated amount per unit surface area of binder solution layer (mg/cm²)/total coated amount obtained by combining the coated amount of binder per unit surface area of the binder solution layer and the coated amount of binder per unit surface area of the compound material paste layer (mg/cm²)]×100, and a binder division rate of 80% (Sample 11), for example, means that 80% of the entire amount of binder coated, when expressed as a weight ratio, is introduced into the binder solution layer, while the remaining 20% is introduced into the compound material paste layer.

TABLE 3 Binder Peel division rate (%) strength (N/m) Sample 7  0 1.16 (ordinary electrode) Sample 8  50 2.05 Sample 9  60 2.22 Sample 10  70 2.40 Sample 11  80 2.50 Sample 12  90 2.51 Sample 13  95 2.50 Sample 14 100 2.33

Adhesion between the current collector 10 and the negative electrode compound material layer 20 of the negative electrode sheets relating to Samples 8 to 14 was evaluated with a 90° peel test using a tensile tester. Those results are shown in FIG. 10 and Table 3. FIG. 10 is a graph indicating the relationship between binder division rate and peel strength, with binder division rate (%) plotted on the horizontal axis and peel strength (N/m) plotted on the vertical axis.

As is clear from FIG. 10 and Table 3, peel strength was confirmed to increase as binder division rate increased (namely, as the amount of the binder allocated to the binder solution layer increased), and adhesion between the current collector and the compound material layer was confirmed to be favorable. In the case of the prototype negative electrode sheets produced in this example, extremely high peel strength of 2.1 N/m or more was realized by making the binder division rate 60% or more. However, if the binder division rate is made to be 100% (in which all of the binder is introduced into the binder solution layer), separation of the active material occurs in the surface portion of the compound material layer, thereby causing a slight decrease in peel strength. On the basis of these results, the binder division rate was determined to be suitably within the range of roughly 60 to 100%, preferably within the range of roughly 70 to 99%, and more preferably within the range of roughly 80 to 98% (for example, about 95%).

Test Example 4

In Sample 15, a test lithium secondary battery was constructed using the negative electrode sheet of Sample 3. In addition, in Sample 16, a negative electrode sheet was produced in the same manner as Sample 3 with the exception of reducing the coated amount of binder by half (roughly 0.01225 mg/cm² (as solid content)), and a test lithium secondary battery was constructed using this negative electrode sheet. In addition, for the sake of comparison, a test lithium secondary battery was constructed in Sample 17 using the negative electrode sheet (ordinary electrode) of Sample 7. The alternating current impedance of each test battery was measured to evaluate the low-temperature reactive resistance (mΩ) of these batteries. Furthermore, the test lithium batteries were constructed in the manner described below.

LiNiO₂ powder serving as positive electrode active material, acetylene black (AB) serving as an electrically conductive material and polyvinylidene fluoride (PVDF) serving as binder were mixed in N-methylpyrrolidone (NMP) so that the weight ratio of these materials was 88:10:2 to prepare a positive electrode compound material paste. This positive electrode compound material paste was then coated in the form of strips on both sides of a positive electrode current collector (aluminum foil) followed by drying to produce a positive electrode sheet in which the positive electrode compound material layer was provided on both sides of the positive electrode current collector. The coated amount of the positive electrode compound material paste was adjusted to about 5.0 mg/cm² (as solid content) per side.

The resulting positive electrode compound material layer of the positive electrode sheet was stamped out to a size measuring 3 cm×4 cm to produce a positive electrode. In addition, the negative electrode compound material layer of the above-mentioned negative electrode sheet was stamped out to a size of 3 cm×4 cm to produce a negative electrode. An aluminum lead was attached to the positive electrode, a nickel lead was attached to the negative electrode, the two electrodes were arranged in mutual opposition with a separator (using porous polypropylene) interposed there between, and the electrodes were inserted into a laminated pouch together with a non-aqueous electrolyte to construct a laminated cell 60 shown in FIG. 11. In FIG. 11, reference symbol 61 indicates the positive electrode, reference symbol 62 indicates the negative electrode, reference symbol 63 indicates the separator impregnated with electrolyte, and reference symbol 64 indicates the laminated pouch. Furthermore, a mixed solvent containing ethylene carbonate (EC), dimethyl carbonate (DMC) and ethylmethyl carbonate (EMC) at a volume ratio of 3:4:3, which also contained LiPF₆ as a supporting salt at a concentration of about 1 mol/liter, was used for the non-aqueous electrolyte. Subsequently, a test lithium secondary battery was obtained by carrying out initial charge-discharge treatment in accordance with ordinary methods.

The alternating current impedance of the lithium secondary batteries produced in this manner was measured at a testing temperature of 0° C. to evaluate their reactive resistance (mΩ). The measurement conditions for alternating current impedance consisted of an alternating current applied voltage of 5 mV and frequency range of 0.001 to 100,000 Hz. The results are shown in Table 4.

TABLE 4 Peel strength Low-temperature reactive (N/m) resistance (mΩ) Sample 15 2.33 384 Sample 16 1.88 356 Sample 17 1.16 432 (ordinary electrode)

As is clear from Table 4, in the battery of Sample 17 (ordinary electrode) in which the negative electrode sheet was produced without coating the binder solution layer onto the current collector, the surface layer of the compound material layer became binder-rich due to segregation of binder during drying, thereby causing the reactive resistance value to exceed 430 mΩ. In contrast, in the battery of Sample 15 in which the binder solution layer was coated onto the current collector, binder gathered in the vicinity of the current collector while the amount of the binder in the surface layer decreased, thereby resulting in a considerable decrease in the reactive resistance value as compared with Sample 17 (ordinary electrode). Moreover, an extremely low reactive resistance value of 360 mΩ or less was able to be realized by reducing the coated amount of binder by half (Sample 16).

The following provides an explanation of an embodiment of a lithium secondary battery constructed using the negative electrode (negative electrode sheet) 30 produced by applying the method described above with reference to the schematic drawing shown in FIG. 8. This lithium secondary battery 100 uses the negative electrode (negative electrode sheet) 30 produced by applying the above-mentioned method using the binder solution 50 for the negative electrode (negative electrode sheet) 30.

As shown in the drawing, the lithium secondary battery 100 relating to the present embodiment is provided with a case 82 made of metal (and preferably also made of a resin or laminated film). This case (outer container) 82 is provided with a case body 84 in the form of a flat rectangular solid having an open upper end, and a cover 86 that covers the opening. A positive electrode terminal 72, which is electrically connected to a positive electrode 70 of an electrode body 80, and a negative electrode terminal 74, which is electrically connected to the negative electrode 30 of the electrode body, are provided in the top of the case 82 (namely, in the cover 86). For example, the long sheet-like positive electrode (positive electrode sheet) 70 and the long sheet-like negative electrode (negative electrode sheet) 30 are laminated and wound together with a total of two long sheet-like separators (separator sheet) 76, after which the flat, wound electrode body 80, produced by collapsing the resulting wound body by pushing from the lateral direction, is housed within the case 82.

As previously described, the negative electrode sheet 30 has a configuration in which the negative electrode compound material layer 20 consisting mainly of the negative electrode active material is provided on both sides of the long sheet-like negative electrode current collector 10 (see FIG. 1). In addition, the positive electrode sheet 70 has a configuration in which the positive electrode compound material layer composed mainly of the positive electrode active material is provided on both sides of the long sheet-like positive electrode current collector in the same manner as the negative electrode sheet. Furthermore, the electrode production method disclosed herein can be applied to the production of either the positive electrode or negative electrode. The positive electrode sheet 70 may also be a positive electrode sheet 70 produced by applying the above-mentioned method using the binder solution 50 in the same manner as the negative electrode sheet 30. A portion at which an electrode compound material layer is not formed, where the above-mentioned electrode compound material layer is not provided, is formed on either side of one end in the direction of width of the electrode sheets 30 and 70.

During the lamination described above, the positive electrode sheet 70 and the negative electrode sheet 30 are superimposed while shifting in the direction of width so that the portion of the positive electrode sheet 70 where the positive electrode compound material layer is not formed and the portion of the negative electrode sheet 30 where the negative electrode compound material layer is not formed respectively protrude from both sides of the separator sheets 76 in the direction of width. As a result, the portions of the positive electrode sheet 70 and the negative electrode sheet 30 where the electrode compound material layers are not formed respectively protrude to the outside from a winding core portion (namely, the portion where the portions of the positive electrode sheet 70, the negative electrode sheet 30 where the electrode compound material layers, and the two separator sheets 76 are not formed are tightly wound) in the horizontal direction relative to the direction of winding of the wound electrode body 80. A positive electrode lead terminal 78 and a negative electrode lead terminal 79 are respectively provided on the positive electrode side protruding portion (namely, the portion where the positive electrode compound material layer is not formed) 70A and the negative electrode side protruding portion (namely, the portion where the negative electrode compound material layer is not formed) 30A, and are electrically connected to the above-mentioned positive electrode terminal 72 and the negative electrode terminal 74, respectively.

Furthermore, constituent elements that compose the wound electrode body 80 other than the negative electrode sheet 30 may be same as those of an electrode body of a conventional lithium secondary battery and there are no particular limitations thereon. For example, the positive electrode sheet 70 can be formed by applying a positive electrode compound material layer consisting mainly of a lithium secondary battery positive electrode active material onto a long positive electrode current collector. Aluminum foil or other metal foil suitable for a positive electrode is preferably used for the positive electrode current collector. One type or two or more types of materials conventionally used in lithium secondary batteries can be used without any particular limitations for the positive electrode active material. Preferable examples include those composed mainly of a lithium transition metal composite oxide containing as constituent metal elements lithium and one type or two or more types of transition metal elements, such as LiMn₂O₄, LiCoO₂ or LiNiO₂.

In addition, a preferable example of the separator sheets 76 used between the positive and negative electrode sheets 70 and 30 is that composed of a porous polyolefin-based resin. Furthermore, the separator may not be required in the case of using a solid electrolyte or gelled electrolyte for the electrolyte (namely, the electrolyte per se can function as a separator in such cases).

The wound electrode body 80 is housed in the case body 84 through the opening in the upper end of the case body 84, and an electrolyte solution containing a suitable electrolyte is arranged (filled) in the case body 84. The electrolyte is, for example, a lithium salt such as LiPF₆. For example, a non-aqueous electrolyte solution can be used that is obtained by dissolving a suitable amount (such as a concentration of 1 M) of a lithium salt such as LiPF₆ in a mixed solvent (having a weight ratio of, for example, 1:1) of diethyl carbonate and ethylene carbonate.

Subsequently, the opening is sealed by welding to the cover 86, for example, to complete assembly of the lithium secondary battery 100 relating to the present embodiment. The sealing process of the case 82 and the arrangement (filling) process of the electrolyte may be the same as techniques carried out in the production of conventional lithium secondary batteries, and are not intended to characterize the present invention. Construction of the lithium secondary battery 100 relating to the present embodiment is completed in this manner.

Since the lithium secondary battery 100 constructed in the manner described above is constructed using an electrode produced by applying the method using the binder solution 50 as previously described for at least one of the electrodes, it demonstrates superior battery performance. For example, by constructing a battery using the above-mentioned electrode, the lithium secondary battery 100 can be provided that satisfies at least one (and preferably both) of high cycle durability and superior productivity.

Furthermore, the technology disclosed herein includes that described below.

(1) A method for producing a battery electrode employing a configuration in which a compound material layer containing an active material is retained on a current collector, wherein,

the compound material layer is formed by applying a compound material paste, in which the active material is dispersed in a prescribed solvent, to the current collector followed by drying, and

formation of the compound material layer includes the following steps:

a step of preparing a binder solution, in which a binder is dispersed in a solvent capable of separating into two phases with the solvent of the compound material paste, and which has a higher specific gravity than the compound material paste,

a step of forming a binder layer (or in other words, a binder solution layer) by applying the binder solution to the surface of the current collector,

a step of depositing the binder layer and the compound material paste (namely, the compound material paste layer) on the surface of the current collector by applying the compound material paste to the current collector on which the binder layer has been formed over the binder layer, and

a step of obtaining an electrode in which the compound material layer is formed on the current collector by drying both the deposited binder layer and compound material paste.

(2) In the technology disclosed herein, the solvent of the compound material paste contains water, and the solvent of the binder solution contains carbon tetrachloride or a fluorine-based liquid.

(3) In the technology disclosed herein, the solvent of the compound material paste contains N-methylpyrrolidone, and the solvent of the binder solution contains carbon tetrachloride or a fluorine-based liquid.

(4) In the technology disclosed herein, the binder layer is formed by spraying the binder solution.

(5) According to the present invention, a battery is also provided that is constructed using an electrode obtained according to any of the above-mentioned methods disclosed herein. Namely, the battery is provided with an electrode produced according to any of the methods described in (1) to (4) above, wherein

the electrode has a configuration in which a compound material layer containing an active material is retained on a current collector, and

when the compound material layer is divided into two parts in the direction of thickness, the amount of the binder contained in the divided part arranged on the current collector side of the compound material layer is greater than the amount of the binder contained in the divided portion arranged on the opposite side from the current collector.

INDUSTRIAL APPLICABILITY

According to the present invention, a method for producing a battery electrode is provided that enables adhesive strength between a current collector and a compound material layer to be enhanced.

Since the battery (such as a lithium secondary battery) relating to the present invention has superior battery performance as previously described, it can be used particularly preferably as a power supply for a motor installed in a vehicle such as an automobile. Thus, as schematically shown in FIG. 9, the present invention provides a vehicle (typically an automobile, and particularly an automobile equipped with a motor in the manner of a hybrid vehicle, electric vehicle or fuel cell vehicle) 1 that is equipped with this battery (which can also be in the form of a battery assembly) 100 as the power supply thereof. 

The invention claimed is:
 1. A method for producing a battery electrode employing a configuration in which a compound material layer containing an active material and a binder is retained on a current collector, the method comprising: forming a first layer of a binder solution in a liquid phase, comprising a first binder and a solvent, on to the current collector; depositing a liquid phase bilayer consisting of the first layer of the binder solution and a second layer of a compound material paste comprising the active material and a solvent on the current collector by applying the compound material paste over the first layer of the binder solution, wherein the solvent used for the binder solution has a specific gravity higher than the solvent of the compound material paste, and the binder solution is composed so as to be able to maintain a state of being separated from the compound material paste at least over a fixed period of time; and drying the liquid phase bilayer.
 2. The method according to claim 1, wherein a viscosity of at least one of the binder solution and the compound material paste is adjusted to 1000 mPa·s or more.
 3. The method according to claim 1, wherein the viscosity of one of the binder solution and the compound material paste is adjusted to 2000 mPa·s or more, while the viscosity of the other one of the binder solution and the compound material paste is adjusted to 1000 mPa·s or less.
 4. The method according to claim 1, wherein a difference in SP values between the binder solution and the compound material paste is adjusted to 2.0 or more.
 5. The method according to claim 1, wherein the solvent of the compound material paste is water or N-methylpyrrolidone, and the solvent of the binder solution is carbon tetrachloride or a fluorine-based liquid.
 6. The method according to claim 1, wherein the second layer of the compound material paste contains a second binder, and a content of the first binder per unit surface area of the first layer of the binder solution is 60% by weight or more based on a total combined weight of a content of the first binder per unit surface area of the first layer of the binder solution and a content of the second binder per unit surface area of the second layer of the compound material paste.
 7. The method according to claim 6, wherein the second binder is composed of the same material as that of the first binder.
 8. The method according to claim 1, wherein the solvent present in the second layer of the compound material paste is volatilized at a rate of 0.2 mg/s·cm² or more.
 9. The method according to claim 1, wherein the binder solution consists of the first binder and the solvent and does not include a conductive material. 